OBJECTIVES: Most information about pharmacokinetics of antimicrobial agents is obtained from studies in healthy volunteers. However, antibiotics are therapeutically used in infected patients with very different pharmacokinetic properties compared with healthy individuals. PATIENTS AND METHODS: In a single-centre, prospective, open-label study, 17 adult critically ill patients with early-onset ventilator-associated pneumonia (VAP) were treated with 1 g of ertapenem infusion once a day. Blood and urine samples were collected before and at different time-points up to 24 h after medication on day 1. Concentrations of ertapenem in plasma were determined with a validated HPLC method. Free-drug concentrations were estimated using a two-class binding site equation. RESULTS: The overall clinical success rate of the assessable cases was 66.7% (12/16). Pharmacokinetic parameters of ertapenem in our critically ill patients were clearly different when compared to those reported in the literature for healthy volunteers. The enhanced V(z) (17 vs. 8 L) and CL(TOT) (43 vs. 20 mL/min) with resulting lower C(max) (90 vs. 253 mg/L) and AUC(0-infinity) (418 vs. 817 mg x h/L) values were mainly related to hypoalbuminaemia (range 9.2-25.6 g/L) in our patient population. A population pharmacokinetic analysis using the NONMEM program indicated creatinine clearance as a significant covariate for explaining the between-subject variability of ertapenem in the patient population. Estimated free plasma concentrations of ertapenem exceeded a MIC(90) of 2 mg/L only for 6 h (25%) after infusion. CONCLUSIONS: For an adequate dose adjustment of highly protein-bound drugs like ertapenem, knowledge of actual albumin concentrations is necessary. A shortening of the dosage interval or continuous infusion of ertapenem should be considered to ensure optimal free concentrations in critically ill patients with severe hypoalbuminaemia and normal renal function.
OBJECTIVES: Most information about pharmacokinetics of antimicrobial agents is obtained from studies in healthy volunteers. However, antibiotics are therapeutically used in infectedpatients with very different pharmacokinetic properties compared with healthy individuals. PATIENTS AND METHODS: In a single-centre, prospective, open-label study, 17 adult critically illpatients with early-onset ventilator-associated pneumonia (VAP) were treated with 1 g of ertapenem infusion once a day. Blood and urine samples were collected before and at different time-points up to 24 h after medication on day 1. Concentrations of ertapenem in plasma were determined with a validated HPLC method. Free-drug concentrations were estimated using a two-class binding site equation. RESULTS: The overall clinical success rate of the assessable cases was 66.7% (12/16). Pharmacokinetic parameters of ertapenem in our critically illpatients were clearly different when compared to those reported in the literature for healthy volunteers. The enhanced V(z) (17 vs. 8 L) and CL(TOT) (43 vs. 20 mL/min) with resulting lower C(max) (90 vs. 253 mg/L) and AUC(0-infinity) (418 vs. 817 mg x h/L) values were mainly related to hypoalbuminaemia (range 9.2-25.6 g/L) in our patient population. A population pharmacokinetic analysis using the NONMEM program indicated creatinine clearance as a significant covariate for explaining the between-subject variability of ertapenem in the patient population. Estimated free plasma concentrations of ertapenem exceeded a MIC(90) of 2 mg/L only for 6 h (25%) after infusion. CONCLUSIONS: For an adequate dose adjustment of highly protein-bound drugs like ertapenem, knowledge of actual albumin concentrations is necessary. A shortening of the dosage interval or continuous infusion of ertapenem should be considered to ensure optimal free concentrations in critically illpatients with severe hypoalbuminaemia and normal renal function.
Authors: J C Bader; E A Lakota; G E Dale; H S Sader; J H Rex; P G Ambrose; S M Bhavnani Journal: Antimicrob Agents Chemother Date: 2019-05-24 Impact factor: 5.191
Authors: Belén Gutiérrez-Gutiérrez; Robert A Bonomo; Yehuda Carmeli; David L Paterson; Benito Almirante; Luis Martínez-Martínez; Antonio Oliver; Esther Calbo; Carmen Peña; Murat Akova; Johann Pitout; Julia Origüen; Vicente Pintado; Elisa García-Vázquez; Oriol Gasch; Axel Hamprecht; Nuria Prim; Mario Tumbarello; German Bou; Pierluigi Viale; Evelina Tacconelli; Manel Almela; Federico Pérez; Helen Giamarellou; José Miguel Cisneros; Mitchell J Schwaber; Mario Venditti; Warren Lowman; Joaquín Bermejo; Po-Ren Hsueh; Marta Mora-Rillo; Irene Gracia-Ahulfinger; Alvaro Pascual; Jesús Rodríguez-Baño Journal: J Antimicrob Chemother Date: 2016-02-22 Impact factor: 5.790
Authors: Elizabeth A Lakota; Cornelia B Landersdorfer; Li Zhang; Anne N Nafziger; Joseph S Bertino; Sujata M Bhavnani; Alan Forrest Journal: Antimicrob Agents Chemother Date: 2018-09-24 Impact factor: 5.191
Authors: Rachel F Eyler; A Mary Vilay; Ahmed M Nader; Michael Heung; Melissa Pleva; Kevin M Sowinski; Daryl D DePestel; Fritz Sörgel; Martina Kinzig; Bruce A Mueller Journal: Antimicrob Agents Chemother Date: 2013-12-09 Impact factor: 5.191